日照—连云港地区重磁异常特征及其构造意义

航空重力、磁力测量是解决海陆过渡区地球物理资料不连续问题的有效途径,所获取的数据为进一步认识苏鲁造山带西段断裂展布、大地构造属性等基础地质问题提供了科学依据.基于最新高精度航空重磁数据,编制了日照-连云港地区1:25万重力、磁力异常图,结合区域地质资料,分析重、磁异常特征,在日照-连云港地区圈定了郯庐断裂带、桑墟-连云港断裂、东海-赣榆断裂、五莲-桃园断裂等基底断裂构造.研究认为苏鲁造山带南部边界为桑墟-连云港断裂（连黄断裂）,以该断裂为界,北侧基底为华北板块组成部分,断裂南侧为下扬子板块基底;以东海-赣榆断裂为界,苏鲁造山带可分为南部和北部,两部分在后期构造活动方面差异显著.      

锡林浩特-西乌旗地区航磁场特征与构造单元划分

以2009年内蒙古锡林浩特-西乌旗地区1∶5万比例尺的航磁资料为基础,结合地质、遥感、重力等资料,研究了该区不同构造单元的航磁磁场特征,在综合分析的基础上,对该区的构造单元进行了划分。对比分析显示,基于航磁推断的华北板块北缘断裂与地质上研究结果基本吻合,但锡林浩特地块北缘深断裂位置应从地质位置处北移10~20 km。     

日照—连云港地区主要断裂重磁异常特征

为满足1∶25万海洋区域地质调查需求,解决海陆过渡区的基础地质问题,在统一编制1∶25万重力异常图和磁力异常图的基础上,分析日照—连云港地区主要断裂的重磁异常特征。结合区域地质资料,探讨郯庐断裂沂水段、桑墟—连云港断裂、东海—赣榆断裂的重磁异常特征及其地质意义。结果表明:昌邑—大店断裂是郯庐断裂沂水段的主断裂;作为苏鲁造山带的南部边界,桑墟—连云港断裂控制了基底、地层和岩浆岩的分布;东海—赣榆断裂将苏鲁造山带分割为南、北2部分。这些新认识为日照—连云港地区基础地质研究提供了重要参考。     

甘肃北山旧井地区晚第四纪活动断裂分布及其构造意义

通过对甘肃北山地区遥感影像分析、地质填图和断裂活动性研究,探讨了北山地区晚第四纪以来的变形机制。结合青藏高原北部区域构造应变、应力场,认为北山地区现今构造格局是在印度板块与欧亚板块相碰撞形成的北东向挤压构造应力场的作用下,重新激活东西向的晚古生代、中生代断裂,并产生北东向新生断裂。说明印度板块与欧亚板块相碰撞并持续向北运移所产生的构造变形不仅局限于青藏高原内部及其边界,更影响到青藏高原以北的地区。     

日照—连云港地区主要断裂重磁异常特征

为满足1:25万海洋区域地质调查需求,解决海陆过渡区的基础地质问题,在统一编制1:25万重力异常图和磁力异常图的基础上,分析日照—连云港地区主要断裂的重磁异常特征。结合区域地质资料,探讨郯庐断裂沂水段、桑墟—连云港断裂、东海—赣榆断裂的重磁异常特征及其地质意义。结果表明: 昌邑—大店断裂是郯庐断裂沂水段的主断裂; 作为苏鲁造山带的南部边界,桑墟—连云港断裂控制了基底、地层和岩浆岩的分布; 东海—赣榆断裂将苏鲁造山带分割为南、北2部分。这些新认识为日照—连云港地区基础地质研究提供了重要参考。     

新疆比勒提地区断裂构造磁异常信息提取及解释简

比勒提地区位于新疆西南天山,以该区1∶50000高精度磁测数据为基础,采用解析延拓、方向导数等技术手段提取与断裂构造有关的磁异常信息,对区域内构造进行识别,结合标本物性参数统计,对引起磁异常的原因进行分析。对区域磁异常向上延拓及求一阶导数后进行对比,圈定4个特征异常带A1~A4,结合地质资料,识别出4条断裂构造FW1~FW4,FW1和FW2对应喀拉铁克断裂及其次级断裂,FW3为构造动力作用产生的强片理化带,FW4为隐伏断裂,表明高精度磁法测量在本区能有效识别断裂并反映其分布。     

新疆比勒提地区断裂构造磁异常信息提取及解释

比勒提地区位于新疆西南天山,以该区1：50000高精度磁测数据为基础,采用解析延拓、方向导数等技术手段提取与断裂构造有关的磁异常信息,对区域内构造进行识别,结合标本物性参数统计,对引起磁异常的原因进行分析。对区域磁异常向上延拓及求一阶导数后进行对比,圈定4个特征异常带A1-A4,结合地质资料,识别出4条断裂构造FW1-FW4,FW1和FW2对应喀拉铁克断裂及其次级断裂,FW3为构造动力作用产生的强片理化带,FW4为隐伏断裂,表明高精度磁法测量在本区能有效识别断裂并反映其分布。     

低飞航磁技术在江西朱溪矿区中的应用

为验证低飞航磁技术在推断断裂带和预测成矿远景区中的应用效果,以江西朱溪矿区以往的地质构造、物化探工作为背景,对朱溪测区的低飞航磁数据进行向上延拓和梯度处理,即总梯度模、斜导数和垂向一阶导数计算。将计算后的多幅异常等值线图与测区的区域地质构造及江西矿区成矿特点相结合,在该地区共推断出地质断裂8条,构造走向为NE向、近EW向及NW向。其中,NE向断裂为该区域主要的深大断裂,形成于下扬子板块和上华夏板块之间由于推覆构造所产生的压挤作用,主要位于塔前—赋春断裂带和双田—石劈山断裂带附近;近EW向和NW向断裂为次生断裂,近EW向断裂可能由九江—德兴断裂带产生。同时,通过分析朱溪矿区矽卡岩矿床所具有的特殊磁梯度异常现象,共推断成矿远景区4个,主要位于断裂带附近。     

基于重磁多尺度边缘检测的长江中下游成矿带构造格架研究

采用重磁多尺度边缘检测方法,对长江中下游成矿带区域重力和航磁数据进行了边缘检测,结合大地电磁剖面和地质资料,建立了长江中下游地区构造格架.根据重磁多尺度边缘检测结果,重新厘定了断裂系统的展布位置,确定了宁芜、庐枞等火山岩盆地的准确边界,划分了板块、火山岩盆地等横向结构的边界.认为长江深断裂沿安庆-铜陵北-芜湖-马鞍山-...     

大兴安岭成矿带铅锌多金属矿床成矿规律

1 区域地质概况大兴安岭地区南至华北地台北缘断裂,北界为蒙古-鄂霍次克褶皱系,东至北北东向的嫩江-白城断裂与松辽盆地为界,大兴安岭属东西向延伸的天山-兴蒙褶皱系的东段.在地形上大兴安岭西坡远比东坡宽缓.该成矿带由西伯利亚板块东南大陆边缘和华北板块北部大陆边缘组成.     

Définition d'une limite multicritère ; stratigraphie du passage Campanien–Maastrichtien du site géologique de Tercis (Landes,SW France)Definition of a multi-criteria boundary; stratigraphy of the Campanian–Maastrichtian interval of the geological site at Tercis (Landes,SW France)

Lithostratigraphy, physicochemical stratigraphy, biostratigraphy, and geochronology of the 77–70 Ma old series bracketing the Campanian–Maastrichtian boundary have been investigated by 70 experts. For the first time, direct relationships between macro- and microfossils have been established, as well as direct and indirect relationships between chemo-physical and biostratigraphical tools. A combination of criteria for selecting the boundary level, duration estimates, uncertainties on durations and on the location of biohorizons have been considered; new chronostratigraphic units are proposed. The geological site at Tercis is accepted by the Commission on Stratigraphy as the international reference for the stratigraphy of the studied interval. To cite this article: G.S. Odin, C. R. Geoscience 334 (2002) 409–414.     

Quaternary stresses revealed by calcite twinning inversion: insights from observations in the Savonnières underground quarry (eastern France)

Calcite samples were extracted both from the rock matrix and the superficial coating of a karstified fault plane of an underground quarry, located in the eastern border of the Paris basin. The karstification is dated as Quaternary. Analysis of mechanical calcite twinning reveals that only the calcite matrix has also undergone a compression trending WNW that can be attributed to the Mio-Pliocene alpine collision. Both coating and matrix have undergone a strike-slip regime with σ₁ roughly trending north–south, that could correspond to the regional present-day state of stress, a strike-slip compression rather trending NNW, modified by local phenomena. To cite this article: M. Rocher et al., C. R. Geoscience 335 (2003).     

NONMETALS DEPOSITS

正20141520 Bo Ying(Key Laboratory of Metallogeny and Mineral Assessment,MLR,Beijing 100037,China);Liu Chenglin Saline Spring Hydrochemical Characteristics and Indicators for Potassium Exploration in Southwestern and Northern Tarim Basin,Xinjiang(Acta Geoscientica Sinica,ISSN1006-3021,CN11-3474/P,34(5),2013,p.594-602,5 illus.,3 tables,28 refs.)     

MATHEMATICAL GEOLOGY

正20141243Chen Ge(Hangzhou Research Institute of Petroleum Geology,PetroChina,Hangzhou 310023,China);Si Chunsong Study on Sedimentary Numerical Simulation Method of Fan Delta Sand Body(Journal of Geology,     

PROSPECTING EXPLORATION

正20142599Chen Sanming(Guangxi Key Laboratory of Concealed Deposits Exploration,Guilin University of Technology,Guilin541004,China);He Yuzhou Block Model and Reserves Estimation of Panzhihua Iron Deposit Based on 3D Geological Modeling(Journal of Guilin University of Technology,ISSN1674-9057,CN45-1375/N,33(4),2013,p.610-615,9illus.,1table,15refs.)     

STRUCTURAL GEOLOGY

正20140594 Bai Daoyuan(Hunan Institute of Geology Survey,Changsha 410016,China);Zhong Xiang Faults in the Jingzhou Basin and Their Tectonic Settings(Geotectonica et Metallogenia,ISSN1001-1552,CN44-1595/P,37(2),2013,p.173-183,6illus.,59refs.)Key words:basin evolution,tectonic setting,South China In the Upper Paleozoic and Jurassic se-     

STRUCTURAL GEOLOGY

正20141912Cao Hui(State Key Laboratory for Continental Tectonics and Dynamics,Institute of Geology,Chinese Academy of Geological Sciences,Beijing 100037,China)Gravitational Collapse and Folding during Orogenesis:A Comparative Study of FIA Trends and Fold Axial Plane Traces(Geology in China,ISSN1000-3657,CN11-1167/P,40(6),2013,p.1818-1828,9illus.,35refs.,with     

PALEOZOOLOGY

正20141609 Chen Guiying(College of Earth Sciences,Guilin University of Technology,Guilin 541004,China);Han Nairen New Materials of Stylophora from the Upper Cambrian of the Jingxi Area,Guangxi,South China(Acta Palaeontologica Sinica,ISSN0001-6616,CN32-1188Q,52(3),2013,p.288-293,2 illus.,12 refs.)Key words:Stylophora,Guangxi     

GEOPHYSICS

正20140634 Cao Lingmin(Key Laboratory of Marine Geology and Environment,Institute of Oceanology,Chinese Academy of Sciences,Qingdao 266071,China);Xu Yi Finite Difference Tomography of the Crustal Velocity Structure in Tengchong,Yunnan Province(Chinese Journal of Geophysics,ISSN0001-5733,CN11-2074/P,56(4),2013,p.1159-1167,6illus.,35refs.,with English abstract)